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Summary

Stay focused on the fundamentals with Paull Offering a new, focused approach to circuit analysis, Clayton Paul's Paul's Fundamentals of Electric Circuit Analysis helps readers master essential circuit analysis skills in a one-semester course. Paul covers all the important topics, while minimizing unnecessary detail, so that students can develop a lasting set of valuable analysis skills. Focused on basic skills . The text emphasizes the three most important electric circuit analysis skills: * Resistive circuit analysis, including controlled sources and op amps * Analysis of circuits in the sinusoidal steady state (the phasor method) * Analysis of circuits in the time domain in response to a disturbance (switching operations and the unit step and unit impulse responses) Focused on student success . Fundamentals of Electric Circuit Analysis provides the learning tools readers need to succeed in circuit analysis. Throughout the text, you'll find: * Example Problems that illustrate each new technique or concept * Exercise Problems that allow readers to apply what they've learned * Real-world application examples * Coverage of circuit analysis tools, such as Spice (PSpice) and Matlab Focused on quality . Maintaining a firm commitment to quality, the author has meticulously reviewed all text material, problems, and solutions. The result is a text that offers accurate content, not distracting errors.

Author Biography

About the Author Clayton R. Paul is Emeritus Professor of Electrical Engineering at the University of Kentucky, and is currently the Sam Nunn Eminent Professor of Aerospace Systems Engineering and Professor of Electrical and Computer Engineering in the Department of Electrical and Computer Engineering at Mercer University in Macon, Georgia. He has written 12 textbooks on electrical engineering subjects, and has published over 200 technical papers, the majority of which are in his primary research area of electromagnetic compatibility of electronic systems. He has received numerous awards for his research and teaching.

Table of Contents

Basic Definitions and Laws

1

(50)

Charge and Electric Forces

2

(1)

Voltage

3

(4)

Current and Magnetic Forces

7

(3)

Lumped Circuit Elements and Power

10

(3)

Kirchhoff's Current Law (KCL)

13

(5)

Kirchhoff's Voltage Law (KVL)

18

(10)

Conservation of Power

28

(2)

Series and Parallel Connections of Elements

30

(2)

Equivalent Circuits

32

(2)

Redrawing Circuits in Equivalent Forms

34

(2)

Application Examples

36

(15)

Residential Power Distribution

36

(3)

Automobile Storage Batteries

39

(12)

Basic Circuit Elements and Analysis Techniques

51

(84)

The Independent Voltage and Current Sources

51

(4)

The Linear Resistor and Ohm's Law

55

(4)

Single-Loop and Single-Node-Pair Circuits

59

(8)

Resistors in Series and in Parallel

67

(10)

Circuit Solution by Circuit Reduction

73

(4)

Voltage and Current Division

77

(8)

Solutions for Circuits Containing More than One Source

85

(5)

Source Transformations

90

(4)

The Controlled (Dependent) Voltage and Current Sources

94

(11)

Analysis of Circuits Containing Controlled Sources

97

(3)

Equivalent Resistance of Circuits Containing Controlled Sources

100

(5)

PSPICE Applications

105

(11)

Application Examples

116

(19)

Ammeters, Voltmeters, and Ohmmeters

116

(2)

An Audio Amplifier

118

(17)

Additional Circuit Analysis Techniques

135

(56)

The Principle of Superposition

135

(7)

The Thevenin Equivalent Circuit

142

(5)

The Norton Equivalent Circuit

147

(6)

Maximum Power Transfer

153

(1)

The Node-Voltage Method

154

(10)

Circuits Containing Voltage Sources

160

(4)

The Mesh-Current Method

164

(9)

Circuits Containing Current Sources

169

(4)

PSPICE Applications

173

(2)

MATLAB Applications

175

(16)

The Operational Amplifier (Op Amp)

191

(22)

The Actual Op Amp versus the Ideal Op Amp

191

(7)

The Inverting Amplifier

194

(1)

Negative Feedback and Saturation

195

(3)

Other Useful Op-Amp Circuits

198

(6)

The Noninverting Amplifier

198

(1)

The Difference Amplifier

199

(2)

The Summer

201

(2)

The Buffer

203

(1)

The Comparator

204

(1)

Applications

204

(2)

A Strain-Gauge Instrumentation Circuit

205

(1)

A Photocell Instrumentation Circuit

206

(1)

PSPICE Applications

206

(7)

The Energy Storage Elements

213

(48)

The Capacitor

213

(7)

Capacitors in Series and in Parallel

218

(2)

Continuity of Capacitor Voltages

220

(1)

The Inductor

220

(6)

Inductors in Series and in Parallel

224

(1)

Continuity of Inductor Currents

225

(1)

Mutual Inductance

226

(8)

The Ideal Transformer

231

(3)

Response of the Energy Storage Elements to DC Sources

234

(1)

The Differential Equations of a Circuit

235

(4)

The Op-Amp Differentiator and Integrator

239

(2)

PSPICE Applications

241

(9)

Application Examples

250

(11)

An Electronic Timer

250

(1)

DC Power Distribution Sag in Digital Logic Circuits

251

(10)

Sinusoidal Excitation of Circuits

261

(100)

The Sinusoidal Source

261

(6)

Representation of General Waveforms via the Fourier Series

263

(3)

Response of Circuits to Sinusodial Sources

266

(1)

Complex Numbers, Complex Algebra, and Euler's Identity

267

(7)

The Phasor (Frequency-Domain) Circuit

274

(6)

Representation of Sinusoidal Sources with Euler's Identity

274

(3)

The Phasor Circuit

277

(3)

Applications of Resistive-Circuit Analysis Techniques in the Phasor Circuit